Display device and display device drive method

ABSTRACT

A display device includes an image display panel whose display is controlled by an image signal, a backlight which includes light sources and lights the image display panel from behind, and a display control section which calculates, based on the image signal, the required luminance value of the backlight for each divided area of the image display panel, calculates a tentative lighting level of each light source based on luminance distribution information for the backlight stored previously and the required luminance values, sets the lighting level of a first light source whose tentative lighting level exceeds an upper limit to the upper limit, determines the lighting level of a second light source whose tentative lighting level does not exceed the upper limit, based on the lighting level of the first light source, luminance distribution information, and required luminance value, and controls the backlight by the lighting levels.

CROSS REFERENCES TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent applicationSer. No. 14/697,820 filed on Apr. 28, 2015, which claims priority toJapanese Priority Patent Application JP 2014-093368 filed in the JapanPatent Office on Apr. 30, 2014, the entire contents of which are herebyincorporated by reference.

BACKGROUND

The embodiments discussed herein are related to a display device and adisplay device drive method.

In recent years the technique of division drive control in a backlightis known as a technique for reducing the power consumption of a displaydevice. Such division drive control in a backlight is performed byadjusting a lighting level of each light source included in thebacklight. Accordingly, a light source used at a high luminance valuewith great frequency deteriorates more rapidly than another lightsource. As a result, the lifetime of an entire display device shortens.In order to solve this problem, a technique for lengthening the lifetimeof a light source is proposed (see, for example, Japanese Laid-openPatent Publication No. 2012-155043).

SUMMARY

There are provided a display device and a display device drive methodwhich reduce the deterioration of a light source.

According to an aspect, there is provided a display device including animage display panel whose display is controlled on the basis of an imagesignal, a backlight which includes a plurality of light sources andwhich lights the image display panel from behind, and a display controlsection which calculates on the basis of the image signal a requiredluminance value of the backlight for an area obtained by dividing adisplay surface of the image display panel, which calculates a tentativelighting level of each of the plurality of light sources on the basis ofluminance distribution information for the backlight stored in advanceand the required luminance value, which sets a lighting level of a firstlight source whose tentative lighting level exceeds a determined upperlimit value to the upper limit value, which calculates and determines alighting level of a second light source whose tentative lighting leveldoes not exceed the upper limit value on the basis of the lighting levelof the first light source, the luminance distribution information, andthe required luminance value, and which controls the backlight by thelighting levels.

The object and advantages of the invention will be realized and attainedby means of the elements and combinations particularly pointed out inthe claims.

It is to be understood that both the foregoing general description andthe following detailed description are exemplary and explanatory and arenot restrictive of the invention.

Additional features and advantages are described herein, and will beapparent from the following Detailed Description and the figures.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 illustrates an example of the structure of a display deviceaccording to a first embodiment;

FIG. 2 illustrates an example of the structure of a display deviceaccording to a second embodiment;

FIG. 3 illustrates an example of the arrangement of pixels on an imagedisplay panel in the second embodiment;

FIG. 4 illustrates an example of the structure of a backlight in thesecond embodiment;

FIG. 5 illustrates an example of the hardware configuration of thedisplay device according to the second embodiment;

FIG. 6 is a functional block diagram of a signal processing section inthe second embodiment;

FIG. 7 illustrates light-source-specific LUTs in the second embodiment;

FIG. 8 is a schematic view of reproduction HSV color space which can bereproduced by the display device according to the second embodiment;

FIG. 9 illustrates an example of the luminance distribution of an imagesignal;

FIG. 10 illustrates an example of tentative lighting level information;

FIG. 11 illustrates luminance distribution detected at the time oflighting each light source at a tentative lighting level;

FIG. 12 illustrates luminance distribution detected at the time oflimiting a lighting level of a light source by an upper limit value;

FIG. 13 illustrates luminance distribution detected at the time ofincreasing a lighting level of a next light source on the right side;

FIG. 14 illustrates luminance distribution detected at the time ofincreasing a lighting level of a next light source on the left side;

FIG. 15 illustrates an example of lighting level information;

FIG. 16 is a flow chart of a procedure for a backlight control process;

FIG. 17 is a flow chart of a procedure for lighting level limitation inlighting level determination;

FIG. 18 is a flow chart of a procedure for first luminance correction inthe lighting level determination; and

FIG. 19 is a flow chart of a procedure for second luminance correctionin the lighting level determination.

DETAILED DESCRIPTION

Embodiments will now be described with reference to the accompanyingdrawings, wherein like reference numerals refer to like elementsthroughout.

Disclosed embodiments are just examples. It is a matter of course that aproper change which suits the spirit of the invention and which willreadily occur to those skilled in the art falls within the scope of thepresent invention. Furthermore, in order to make description clearer,the width, thickness, shape, or the like of each component mayschematically be illustrated in the drawings compared with the realstate. However, it is a simple example and the interpretation of thepresent invention is not restricted.

In addition, in the present invention and the drawings the samecomponents that have already been described in previous drawings aremarked with the same numerals and detailed descriptions of them may beomitted according to circumstances.

(First Embodiment)

A display device according to a first embodiment will be described bythe use of FIG. 1. FIG. 1 illustrates an example of the structure of adisplay device according to a first embodiment.

A display device 1 illustrated in FIG. 1 includes a display controller2, an image display panel 3, and a backlight 5.

The display controller 2 includes a storage section which storesluminance distribution information 2 b in advance, performs requiredluminance value calculation 2 a, tentative lighting level calculation 2c, and lighting level determination 2 d, and controls the luminance ofthe backlight 5.

The image display panel 3 includes (P×Q) pixels arranged in a matrix.The image display panel 3 displays an image on the display surface onthe basis of an image signal.

The backlight 5 includes a plurality of light sources L1, L2, . . . ,and Ln and lights the image display panel 3 from behind. When there isno need to distinguish among the light sources L1, L2, . . . , and Ln,the term “light sources L” will be employed in the followingdescription. The light sources L operate independently of one anotherand a lighting level is set for each light source L. The backlight 5emits, for example, white light from an emission surface opposite thedisplay surface of the image display panel 3 to the display surface.Furthermore, in the backlight 5 division drive control by which alighting level of each light source L is adjusted for controllingluminance according to divided areas is performed.

Each step performed by the display controller 2 and the luminancedistribution information 2 b will be described.

In the required luminance value calculation 2 a, the display controller2 acquires an image signal and calculates on the basis of the imagesignal a required luminance value of the backlight 5 for a divided areaobtained by dividing the display surface of the image display panel 3. Arequired luminance value is lowest luminance at which all pixels in adivided area of the image display panel 3 can reproduce color.Furthermore, a required luminance value is calculated for each dividedarea.

The luminance distribution information 2 b is information for thedistribution of luminance values of the backlight 5 obtained at the timeof lighting each light source L at a determined lighting level. Theluminance distribution information 2 b is generated in advance and isstored in the storage section.

In the tentative lighting level calculation 2 c, the display controller2 calculates a tentative lighting level of a light source L on the basisof a required luminance value and the luminance distribution information2 b. A required luminance value is determined for each divided area. Inthe tentative lighting level calculation 2 c, the display controller 2calculates on the basis of the luminance distribution information 2 b atentative lighting level of a light source L which satisfies a requiredluminance value for each divided area.

In the lighting level determination 2 d, the display controller 2calculates a lighting level of a light source L on the basis of atentative lighting level of the light source L, a required luminancevalue for each divided area, and the luminance distribution information2 b. In particular, the display controller 2 compares a tentativelighting level of a light source L with a specified upper limit valuedetermined in advance. If a tentative lighting level of a first lightsource exceeds the upper limit value, then a lighting level of the firstlight source is set to the upper limit value. If a tentative lightinglevel of a second light source does not exceed the upper limit value,then a lighting level of the second light source is set on the basis ofthe lighting level of the first light source, a required luminancevalue, and the luminance distribution information 2 b. The upper limitvalue set is in the range between a lighting level which does not causethe luminance below the maximum luminance obtained by an image signaland a lighting level corresponding to a peak value of drive current bywhich a light source L is driven. The lighting level of the first lightsource is limited to the upper limit value which is lower than thetentative lighting level of the first light source, so the luminance ofthe backlight 5 for a corresponding divided area is lower than arequired luminance value. Accordingly, a reduction in luminance iscompensated for by increasing a lighting level of the second lightsource whose tentative lighting level does not exceed the upper limitvalue. The display controller 2 determines in this way lighting levelsof plural light sources L which satisfy a required luminance value for adivided area, and controls the luminance of the backlight 5 by thedetermined lighting levels. The first light source or the second lightsource merely indicates the state of a light source L. Each light sourceL goes into one of the two states according to a required luminancevalue for a corresponding block.

With the display device 1 having the above structure, display control ofthe image display panel 3 and division drive control of the backlight 5by the display controller 2 are performed on the basis of an imagesignal. The display controller 2 analyzes the image signal according todivided areas, calculates a required luminance value, and calculates atentative lighting level of a light source L which satisfies therequired luminance value. If a tentative lighting level of a first lightsource exceeds an upper limit value, then a lighting level of the firstlight source is limited to the upper limit value. If a tentativelighting level of a second light source does not exceed the upper limitvalue, then a lighting level of the second light source is determined sothat a reduction in the luminance of the backlight 5 caused by limitinga lighting level of the first light source will be compensated for. Themaximum value of a lighting level of a light source L is limited in thisway to the upper limit value, so the deterioration of the light source Lcaused by driving it at a large lighting level is reduced. Furthermore,a reduction in the luminance of the backlight 5 caused by limiting alighting level of a light source L is compensated for by another lightsource L, so image quality does not degrade.

(Second Embodiment)

A display device according to a second embodiment will now be described.First the structure of a display device will be described, and then aprocess performed by the display device will be described.

FIG. 2 illustrates an example of the structure of a display deviceaccording to a second embodiment.

A display device 10 illustrated in FIG. 2 includes an image outputsection 11, a signal processing section 20, an image display panel 30,an image display panel drive section 40, a backlight 50, and a lightsource drive section 60. The display device 10 is an embodiment of thedisplay device 1 illustrated in FIG. 1.

The image output section 11 outputs an image signal SRGB to the signalprocessing section 20. The image signal SRGB includes an image signalvalue x1 _((p,q)) for a first primary color, an image signal value x2_((p,q)) for a second primary color, and an image signal value x3_((p,q)) for a third primary color. In the second embodiment it isassumed that the first primary color is red, that the second primarycolor is green, and that the third primary color is blue.

The signal processing section 20 is connected to the image display paneldrive section 40 which drives the image display panel 30 and isconnected to the light source drive section 60 which drives thebacklight 50. The signal processing section 20 converts the image signalSRGB to a display signal SRGBW and outputs the display signal SRGBW tothe image display panel drive section 40. In addition to a displaysignal value X1 _((p,q)) corresponding to a first subpixel, a displaysignal value X2 _((p,q)) corresponding to a second subpixel, and adisplay signal value X3 _((p,q)) corresponding to a third subpixel, thedisplay signal SRGBW includes a display signal value X4 _((p,q))corresponding to a fourth subpixel which displays a fourth color. In thesecond embodiment it is assumed that the fourth color is white, forexample. Furthermore, the signal processing section 20 generates alllighting level signals SBL, which are control signals fordivision-driving the backlight 50, on the basis of the image signal SRGBand outputs the all lighting level signals SBL to the light source drivesection 60. The signal processing section 20 is an embodiment of thedisplay controller 2.

The image display panel 30 includes (P×Q) pixels 48 arranged in atwo-dimensional matrix. The image display panel drive section 40includes a signal output circuit 41 and a scanning circuit 42 andperforms display control of the image display panel 30 on the basis ofthe display signal SRGBW.

The backlight 50 is arranged on the rear side of the image display panel30 and emits light to the image display panel 30. By doing so, thebacklight 50 lights the image display panel 30. Furthermore, thebacklight 50 includes a sidelight light source 52 on a side of itsdisplay surface. The sidelight light source 52 includes a plurality oflight sources which operate independently of one another. As a result,division drive control of the backlight 50 is performed. The lightsource drive section 60 performs division drive control of the backlight50 on the basis of the all lighting level signals SBL outputted from thesignal processing section 20. The all lighting level signals SBLindicate lighting levels calculated for the plurality of light sourcesincluded in the sidelight light source 52.

The image display panel 30 and the backlight 50 will now be described bythe use of FIGS. 3 and 4 respectively. The image display panel 30 willbe described first. FIG. 3 illustrates an example of the arrangement ofpixels on the image display panel in the second embodiment.

With the image display panel 30 illustrated in FIG. 3, each of thepixels 48 arranged in a two-dimensional matrix includes a first subpixel49R, a second subpixel 49G, a third subpixel 49B, and a fourth subpixel49W. In the second embodiment, the first subpixel 49R displays red, thesecond subpixel 49G displays green, the third subpixel 49B displaysblue, and the fourth subpixel 49W displays white. However, colors of thefirst subpixel 49R, the second subpixel 49G, and the third subpixel 49Bare not limited to them. The first subpixel 49R, the second subpixel49G, and the third subpixel 49B may display other different colors. Forexample, the first subpixel 49R, the second subpixel 49G, and the thirdsubpixel 49B may display the complementary colors of red, green, andblue respectively. Furthermore, a color of the fourth subpixel 49W isnot limited to white. For example, the fourth subpixel 49W may displayyellow. However, white is effective in reducing power consumption. It isdesirable that if the first subpixel 49R, the second subpixel 49G, thethird subpixel 49B, and the fourth subpixel 49W are lighted at the samelighting level, the fourth subpixel 49W be brighter than the firstsubpixel 49R, the second subpixel 49G, and the third subpixel 49B. Ifthere is no need to distinguish among the first subpixel 49R, the secondsubpixel 49G, the third subpixel 49B, and the fourth subpixel 49W, thenthe term “subpixels 49” will be employed in the following description.

The signal output circuit 41 and the scanning circuit 42 included in theimage display panel drive section 40 are electrically connected to thesubpixels 49R, 49G, 49B, and 49W of the image display panel 30 viasignal lines DTL and scanning lines SCL respectively. The subpixels 49are connected not only to the signal lines DTL but also to the scanninglines SCL via switching elements (such as thin film transistors (TFTs)).The image display panel drive section 40 selects subpixels 49 by thescanning circuit 42 and outputs image signals in order from the signaloutput circuit 41. By doing so, the image display panel drive section 40controls the operation (light transmittance) of the subpixels 49.

The backlight 50 will now be described by the use of FIG. 4. FIG. 4illustrates an example of the structure of the backlight in the secondembodiment.

The backlight 50 illustrated in FIG. 4 includes a light guide plate 54and the sidelight light source 52 in which light sources L1, L2, L3, L4,L5, L6, L7, L8, L9, and L10 are arranged opposite an incident surface Ethat is at least one side of the light guide plate 54. The light sourcesL1, L2, L3, L4, L5, L6, L7, L8, L9, and L10 are light-emitting diodes(LEDs) which emit light of the same color (white, for example), andcontrol current values or duty ratios independently of one another. Ifthere is no need to distinguish among the light sources L1, L2, L3, L4,L5, L6, L7, L8, L9, and L10, then the term “light sources L” will beemployed in the following description. The light sources L are arrangedalong the one side of the light guide plate 54. It is assumed that thedirection in which the light sources L are arranged is a light sourcearrangement direction LY. Light emitted from the light sources L isinputted from the incident surface E to the light guide plate 54 in anincident direction LX intersect or perpendicular to the light sourcearrangement direction LY. Furthermore, light which enters the lightguide plate 54 is emitted from a surface opposite the image displaypanel 30. Lights which are emitted from the light sources L and whichare emitted from the light guide plate 54 to the rear of the imagedisplay panel 30 have different luminance distributions according to thepositions at which the light sources L are arranged.

The light source drive section 60 adjusts the values of current suppliedto the light sources L or duty ratios on the basis of all lighting levelsignals SBL outputted from the signal processing section 20. By doingso, the light source drive section 60 controls the amounts of the lightsof the light sources L and controls the luminance (intensity of thelight) of the backlight 50.

The hardware configuration of the display device 10 will now bedescribed. FIG. 5 illustrates an example of the hardware configurationof the display device according to the second embodiment.

The whole of the display device 10 is controlled by a controller 100.The controller 100 includes a central processing unit (CPU) 101. Arandom access memory (RAM) 102, a read only memory (ROM) 103, and aplurality of peripheral units are connected to the CPU 101 via a bus108.

The CPU 101 is a processor which realizes the processing functions ofthe controller 100.

The RAM 102 is used as main storage of the controller 100. The RAM 102temporarily stores at least a part of an operating system (OS) programor an application program executed by the CPU 101. In addition, the RAM102 stores various pieces of data which the CPU 101 needs to perform aprocess.

The ROM 103 is a read only semiconductor memory and stores an OSprogram, an application program, and fixed data which is not rewritten.Furthermore, a semiconductor memory, such as a flash memory, may be usedas auxiliary storage in place of the ROM 103 or in addition to the ROM103.

The plurality of peripheral units connected to the bus 108 are a displaydriver integrated circuit (IC) 104, an LED driver IC 105, an inputinterface 106, and a communication interface 107.

The image display panel drive section 40 is connected to the displaydriver IC 104. The display driver IC 104 outputs a display signal SRGBWto the image display panel drive section 40 to display an image on theimage display panel 30.

The sidelight light source 52 is connected to the LED driver IC 105. TheLED driver IC 105 drives the sidelight light source 52 by all lightinglevel signals SBL and controls the luminance of the backlight 50.

An input device used for inputting a user's instructions is connected tothe input interface 106. An input device, such as a keyboard, a mouseused as a pointing device, or a touch panel, is connected. The inputinterface 106 transmits to the CPU 101 a signal transmitted from theinput device.

The communication interface 107 is connected to a network 200. Thecommunication interface 107 transmits data to or receives data fromanother computer or a communication apparatus via the network 200.

By adopting the above hardware configuration, the processing functionsin the second embodiment are realized. The above hardware configurationis an example and is changed according to circumstances.

The processing functions of the signal processing section 20 illustratedin FIG. 2 are realized by the controller 100 or the display driver IC104.

If the processing functions of the signal processing section 20 arerealized by the display driver IC 104, then an image signal SRGB isinputted to the display driver IC 104 via the CPU 101. The displaydriver IC 104 converts the image signal SRGB to a display signal SRGBWand controls the image display panel 30. In addition, the display driverIC 104 generates all lighting level signals SBL and outputs them to theLED driver IC 105 via the bus 108.

If the processing functions of the signal processing section 20 arerealized by the CPU 101, then a display signal SRGBW is inputted fromthe CPU 101 to the display driver IC 104. All lighting level signals SBLare also generated by the CPU 101 and are transmitted to the LED driverIC 105 via the bus 108.

The structure of the functions of the signal processing section 20 willnow be described. FIG. 6 is a functional block diagram of the signalprocessing section in the second embodiment.

The signal processing section 20 includes a timing generation unit 21, adisplay signal conversion unit 22, an image analysis unit 23, a lightsource data storage unit 24, a tentative lighting level calculation unit25, and a lighting level determination unit 26. An image signal SRGB isinputted from the image output section 11 to the signal processingsection 20. The image signal SRGB includes color information for animage displayed at the position of each pixel 48.

The timing generation unit 21 generates a synchronization signal STMevery image display frame for synchronizing the operation timing of theimage display panel drive section 40 with that of the light source drivesection 60. The timing generation unit 21 outputs the generatedsynchronization signal STM to the image display panel drive section 40and the light source drive section 60.

The display signal conversion unit 22 calculates, on the basis of thecolor information included in the image signal SRGB, a conversioncoefficient for converting the image signal SRGB to a display signalSRGBW, and uses the conversion coefficient for converting the imagesignal SRGB to a display signal SRGBW. In addition, the display signalconversion unit 22 corrects the display signal SRGBW on the basis ofluminance information for the backlight 50 inputted from the lightinglevel determination unit 26.

On the basis of the image signal SRGB, the image analysis unit 23calculates a required luminance value of the backlight 50 required foreach divided area obtained by dividing a display surface of the imagedisplay panel 30. In the following description each divided area will bereferred to as a block. Any way may be adopted to divide the displaysurface and form blocks. With division drive control of the backlight 50the luminance of the backlight 50 is adjusted according to an image tobe displayed. Accordingly, the image analysis unit 23 analyzes the imagesignal SRGB corresponding to a block and calculates a required luminancevalue required for displaying an image. For example, a conversioncoefficient for converting the image signal SRGB to a display signalSRGBW is calculated on the basis of color information for the firstprimary color, the second primary color, and the third primary colorincluded in the image signal SRGB, and a required luminance value iscalculated on the basis of the conversion coefficient.

The light source data storage unit 24 stores various pieces ofinformation referred to in the signal processing section 20. A luminancevalue of a representative pixel which represents pixels included in adetermined area obtained by dividing the display surface is recorded ina tabular form in luminance distribution information by light sourceincluded in the various pieces of information. In the followingdescription luminance distribution information by light source in atabular form will be referred to as a light-source-specific lookup table(LUT). An light-source-specific LUT is information specific to thedisplay device 10, so it is created in advance and is stored in thelight source data storage unit 24.

FIG. 7 illustrates light-source-specific LUTs in the second embodiment.

A light-source-specific LUT 240 is prepared for each of the lightsources L1 through L10. Luminance values of representative pixels of(m×n) areas obtained by dividing the display surface at the time oflighting only the light source L1 at a determined lighting level arerecorded in a tabular form in an LUT 241. The LUT 241 for the lightsource L1 through an LUT 243 for the light source L10 are created inthis way and are stored in the light source data storage unit 24. If aluminance value of a representative pixel which represents each area isregistered in the light-source-specific LUT 240, the size of thelight-source-specific LUT 240 is small compared with a case whereluminance values of all pixels in each area are registered. As a result,the storage capacity of the light source data storage unit 24 isreduced. When a luminance value of each pixel is needed, it iscalculated by interpolation calculation. The light-source-specific LUT240 is information at the time of lighting one light source L at a time.However, a light-source-specific LUT at the time of simultaneouslylighting a combination of the light sources L1 and L2, a combination ofthe light sources L3 and L4, or the like may be created and stored. Thisreduces the amount of work for creating light-source-specific LUTs andthe storage capacity of the light source data storage unit 24. Acombination of one or more light sources is referred to as a lightsource unit. The light-source-specific LUT 240 is prepared for eachlight source unit. Furthermore, a luminance value is set in a correctedstate in the light-source-specific LUT 240 so as to accommodateluminance irregularity correction. By using this light-source-specificLUT 240, luminance irregularity correction and lighting leveldetermination are performed at the same time.

Description will return to FIG. 6.

The tentative lighting level calculation unit 25 calculates a tentativelighting level of each light source L of the sidelight light source 52on the basis of a required luminance value calculated by the imageanalysis unit 23 and the light-source-specific LUT 240. For example, thetentative lighting level calculation unit 25 tentatively sets atentative lighting level, calculates the luminance distribution of theentire backlight 50 in that state by the use of thelight-source-specific LUT 240, compares the calculated luminancedistribution with the required luminance value, and corrects thetentative lighting level. This operation is repeated at need until atentative lighting level which satisfies the required luminance value isobtained. Alternatively, the tentative lighting level calculation unit25 may find a tentative lighting level which satisfies the requiredluminance value by calculation. The tentative lighting level calculationunit 25 outputs the calculated tentative lighting level to the lightinglevel determination unit 26.

The lighting level determination unit 26 acquires the tentative lightinglevel of each light source L and compares it with an upper limit value.It is assumed that a light source whose tentative lighting level exceedsthe upper limit value at this time is a first light source and that alight source whose tentative lighting level does not exceed the upperlimit value at this time is a second light source. If the first lightsource is not detected, then the tentative lighting level calculated bythe tentative lighting level calculation unit 25 is considered as alighting level. If a first light source is detected, then a lightinglevel of the detected first light source is set to the upper limitvalue. If the luminance of a corresponding block becomes lower than arequired luminance value by limiting a lighting level of the first lightsource, then a lighting level of a second light source adjacent to thefirst light source is increased to compensate for a reduction in theluminance. For example, the lighting level determination unit 26calculates on the basis of the light-source-specific LUT 240 a lightinglevel of the second light source by which the reduction in the luminanceof the corresponding block is compensated for, and adds this lightinglevel to a tentative lighting level of the second light source. By doingso, a lighting level of the second light source is calculated.Alternatively, a tentative lighting level calculation may be performedagain with a lighting level of the first light source considered to befixed. If the calculated lighting level of the second light sourceexceeds the upper limit value, then a lighting level of the second lightsource is set to the upper limit value. After that, the same process isperformed on another second light source adjacent to the second lightsource. A lighting level correction process is repeated in order on asecond light source until the luminance of the corresponding blocksatisfies the required luminance value. The lighting level determinationunit 26 generates in this way all lighting level signals SBL of thelight sources L1 through L10 included in the sidelight light source 52and outputs them to the light source drive section 60. The light sourcedrive section 60 controls the sidelight light source 52 by the alllighting level signals SBL. Furthermore, the lighting leveldetermination unit 26 calculates luminance information for the backlight50 based on the generated all lighting level signals SBL on the basis ofthe light-source-specific LUT 240 and outputs the luminance informationfor the backlight 50 to the display signal conversion unit 22. Thedisplay signal conversion unit 22 may correct a display signal SRGBW onthe basis of the luminance information for the backlight 50.

The operation of the display device 10 having the above structure willbe described.

With the display device 10 each pixel 48 includes the fourth subpixel49W which outputs the fourth color (white, for example). This extendsthe dynamic range of a value in reproduction HSV color space which canbe reproduced by the display device 10. When the display device 10generates a display signal SRGBW from an image signal SRGB, the displaydevice 10 improves the luminance of each pixel by using an expansioncoefficient α as a conversion coefficient. “H” represents hue, “S”represents saturation, and “V” represents a value.

FIG. 8 is a schematic view of reproduction HSV color space which can bereproduced by the display device according to the second embodiment. Asillustrated in FIG. 8, the reproduction HSV color space to which thefourth color has been added has a shape obtained by putting anapproximately trapezoid solid in which, as the saturation S increases,the maximum value of the value V becomes smaller on cylindrical HSVcolor space which the first subpixel 49R, the second subpixel 49G, andthe third subpixel 49B display. The signal processing section 20 storesthe maximum value Vmax(S) of a value expressed with the saturation S inthe reproduction HSV color space which has been extended by adding thefourth color as a variable. That is to say, the signal processingsection 20 stores the maximum value Vmax(S) of a value according to thecoordinates (values) of the saturation S and the hue H for the solidshape of the reproduction HSV color space illustrated in FIG. 8.

The image signal SRGB includes image signal values corresponding to thefirst, second, and third primary colors, so HSV color space of the imagesignal SRGB has a cylindrical shape, that is to say, has the same shapeas a cylindrical portion of the reproduction HSV color space illustratedin FIG. 8 has. Accordingly, the display signal SRGBW is calculated as anexpanded image signal obtained by expanding the image signal SRGB tomake it fall within the reproduction HSV color space. The image signalSRGB is expanded by the use of the expansion coefficient α determined bycomparing the value levels of subpixels of the image signal SRGB in thereproduction HSV color space. By expanding the level of the image signalSRGB by the use of the expansion coefficient α, a display signal valuecorresponding to the fourth subpixel 49W can be made large. Thisincreases the luminance of an entire image. At this time the luminanceof the backlight 50 is reduced to 1/α according to an increase in theluminance of the entire image caused by expanding by the use of theexpansion coefficient α. By doing so, display is performed with exactlythe same luminance as with the image signal SRGB.

The expansion of an image signal SRGB will now be described.

In the signal processing section 20, a display signal value X1 _((p,q))corresponding to the first subpixel 49R, a display signal value X2_((p,q)) corresponding to the second subpixel 49G, and a display signalvalue X3 _((p,q)) corresponding to the third subpixel 49B for a (p,q)thpixel (or a combination of the first subpixel 49R, the second subpixel49G, and the third subpixel 49B) are expressed as:X1_((p,q)) =α·x1_((p,q)) −χ·X4_((p,q))  (1)X2_((p,q)) =α·x2_((p,q)) −χ·X4_((p,q))  (2)X3_((p,q)) =α·x3_((p,q)) −χ·X4_((p,q))  (3)

where α is an expansion coefficient and χ is a constant which depends onthe display device 10. χ will be described later.

In addition, a display signal value X4 _((p,q)) is calculated on thebasis of the product of Min_((p,q)) and the expansion coefficient α,where Min_((p,q)) is the minimum value of image signal values x1_((p,q)), x2 _((p,q)), and x3 _((p,q)). To be concrete, a display signalvalue X4 _((p,q)) is found on the basis ofX4_((p,q))=Min_((p,q))·α/χ  (4)

In expression (4), the product of Min_((p,q)) and the expansioncoefficient α is divided by χ. However, another calculation method maybe adopted. Furthermore, the expansion coefficient α is determined everyimage display frame.

These points will now be described.

On the basis of an image signal SRGB for a (p,q)th pixel including animage signal value x1 _((p,q)) corresponding to the first primary color,an image signal value x2 _((p,q)) corresponding to the second primarycolor, and an image signal value x3 _((p,q)) corresponding to the thirdprimary color, usually saturation S_((p,q)) and value V(S)_((p,q)) inthe cylindrical HSV color space are found fromS _((p,q))=(Max_((p,q))−Min_((p,q)))/Max_((p,q))  (5)V(S)_((p,q))=Max_((p,q))  (6)

where Max_((p,q)) is the maximum value of the image signal value x1_((p,q)), the image signal value x2 _((p,q)), and the image signal valuex3 _((p,q)) included in the image signal SRGB, Min_((p,q)) is theminimum value of the image signal value x1 _((p,q)), the image signalvalue x2 _((p,q)), and the image signal value x3 _((p,q)), thesaturation S has a value in the range of 0 to 1, and the value V(S) hasa value in the range of 0 to (2^(n)−1), where n is a display gradationbit number.

A color filter is not disposed between the fourth subpixel 49W whichdisplays white and an observer of an image. If the first subpixel 49Rwhich displays the first primary color, the second subpixel 49G whichdisplays the second primary color, the third subpixel 49B which displaysthe third primary color, and the fourth subpixel 49W which displays thefourth color are lighted at the same lighting level, then the fourthsubpixel 49W is brighter than the first subpixel 49R, the secondsubpixel 49G, and the third subpixel 49B. It is assumed that when asignal value corresponding to the maximum value of display signal valuescorresponding to the first subpixels 49R is inputted to a first subpixel49R, a signal value corresponding to the maximum value of display signalvalues corresponding to the second subpixels 49G is inputted to a secondsubpixel 49G, and a signal value corresponding to the maximum value ofdisplay signal values corresponding to the third subpixels 49B isinputted to a third subpixel 49B, the luminance of a set of a firstsubpixel 49R, a second subpixel 49G, and a third subpixel 49B includedin a pixel 48 or the luminance of a set of first subpixels 49R, secondsubpixels 49G, and third subpixels 49B included in a group of pixels 48is BN₁₋₃. Furthermore, it is assumed that when a signal valuecorresponding to the maximum value of display signal valuescorresponding to a fourth subpixel 49W included in a pixel 48 or fourthsubpixels 49W included in a group of pixels 48 is inputted to a fourthsubpixel 49W, the luminance of the fourth subpixel 49W is BN₄. That isto say, white which has the maximum luminance is displayed by a set of afirst subpixel 49R, a second subpixel 49G, and a third subpixel 49B andthe luminance of white is BN₁₋₃. As a result, the constant χ whichdepends on the display device 10 is expressed asχ=BN ₄ /BN ₁₋₃

By the way, if the display signal value X4 _((p,q)) is given by theabove expression (4), the maximum value Vmax(S) of a value, in which thesaturation S in the reproduction HSV color space is a variable, isexpressed as:If S≤S₀, thenVmax(S)=(χ+1)·(2^(n)−1)  (7)If S₀<S≤1,thenVmax(S)=(2^(n)−1)·(1/S)  (8)where S ₀=1/(χ+1).

The maximum value Vmax(S) of a value in which the saturation S in thereproduction HSV color space that has been extended by adding the fourthcolor is a variable and which is obtained in this way is stored in, forexample, the signal processing section 20 as a type of lookup table.Alternatively, the maximum value Vmax(S) of a value in which thesaturation S in the reproduction HSV color space is a variable is foundevery time by the signal processing section 20.

The expansion coefficient α is used for expanding the value V(S) in theHSV color space into the reproduction HSV color space and is expressedasα(S)=Vmax(S)/V(S)  (9)

In expansion calculation, the expansion coefficient α is determined onthe basis of, for example, α(S) found for plural pixels 48.

Expansion calculation is performed so that the ratio among the luminanceof the first primary color displayed by (first subpixel 49R+fourthsubpixel 49W), the luminance of the second primary color displayed by(second subpixel 49G+fourth subpixel 49W), and the luminance of thethird primary color displayed by (third subpixel 49B+fourth subpixel49W) will be held, so that a color tone will be held (maintained), andso that a gradation-luminance characteristic (gamma (γ) characteristic)will be held (maintained). Furthermore, if all image signal values are 0or small for a pixel 48 or a group of pixels 48, then the expansioncoefficient α may be calculated with the pixel 48 or the group of pixels48 excluded.

The display signal conversion unit 22 analyzes an image signal SRGB onthe basis of the above procedure and calculates the expansioncoefficient α. The display signal conversion unit 22 calculates theexpansion coefficient α for each pixel. On the basis of at least one ofexpansion coefficients α calculated for pixels in an arbitrary area, thedisplay signal conversion unit 22 determines the expansion coefficient αin the arbitrary area. An arbitrary area may be a pixel or the entiredisplay surface. The display signal conversion unit 22 then converts theimage signal SRGB to a display signal SRGBW by the use of expressions(1), (2), (3), and (4). The display signal conversion unit 22 correctsthe display signal SRGBW after conversion according to the luminance ofthe backlight 50 for a corresponding area. That is to say, the expansioncoefficient α is an embodiment of the conversion coefficient.

The image analysis unit 23 analyzes the image signal SRGB according toblocks on the basis of the above procedure and calculates the expansioncoefficient α for each block. A required luminance value required foreach block is 1/α which is the reciprocal of the expansion coefficientα.

As has been described, by using the expansion coefficient α forperforming division drive control of the backlight 50 and displaycontrol of the image display panel 30, the luminance of the backlight 50is set to a minimum value by which the display device 10 can performcolor reproduction in the reproduction HSV color space. As a result, thepower consumption of the display device 10 is reduced.

The processes performed by the tentative lighting level calculation unit25 and the lighting level determination unit 26 will now be described bythe use of a concrete example illustrated in FIG. 9.

FIG. 9 illustrates an example of the luminance distribution of an imagesignal.

FIG. 9 illustrates luminance distribution detected on the displaysurface on which an image signal SRGB at a point of time is displayed.There is a high luminance area 56 on the display surface whose luminanceis higher than that of the other areas. Control is performed so as tomake the luminance of the corresponding area on the backlight 50 high.In the example of FIG. 9, it is assumed that the display surface isdivided into blocks by division lines which extend in the LX directionand that a division line is drawn between two adjacent light sources Lnand L(n+1). Accordingly, the blocks correspond to the light sources L.For example, blocks including the high luminance area 56 correspond tothe light sources L8 and L9.

Each light source L included in the sidelight light source 52 will bedescribed. The reproduction HSV color space which is illustrated in FIG.8 and which can be reproduced by the display device 10 is realized byexpanding the cylindrical HSV color space in the value direction.Accordingly, luminance included in usage conditions for a light source Lin the reproduction HSV color space which can be reproduced by thedisplay device 10 is higher than luminance included in usage conditionsfor a light source L in the cylindrical HSV color space based on thethree primary colors. As a result, usage conditions for each lightsource L are changed. For example, it is assumed that usage conditionsfor a light source L in the cylindrical HSV color space are an LED peakcurrent of 20 mA and the maximum pulse width modulation (PWM) value 100percent (%). Hereinafter these conditions will be referred to as thereference conditions. For example, an LED peak current of 40 mA and themaximum PWM value 100% are set as usage conditions for a light source Lin the reproduction HSV color space which can be reproduced by thedisplay device 10. With the display device 10 a PWM value required forobtaining the same luminance that is realized on the referenceconditions is half of a PWM value included in the reference conditions.For example, the same luminance that is realized at the maximum PWMvalue 100% included in the reference conditions is obtained at the PWMvalue 50% in the display device 10.

The required luminance value 1/α calculated by the image analysis unit23 by analyzing the image signal SRGB is inputted to the tentativelighting level calculation unit 25. On the basis of a required luminancevalue for each block, the tentative lighting level calculation unit 25determines a tentative lighting level of each light source L so as tosatisfy the required luminance value.

FIG. 10 illustrates an example of tentative lighting level information.

Tentative lighting level information 70 is an example of a tentativelighting level calculated by the tentative lighting level calculationunit 25. A tentative lighting level is set for each of the light sourcesL1 through L10. “Lighting Rate (%)” is a PWM value. “PWM Ratio” is theratio of luminance or an LED current value in use corresponding to aluminance or an LED current value in the reference conditions. Forexample, a PWM ratio is obtained by dividing a lighting rate in use by alighting rate of 50% which obtains the same luminance or current as thatof the reference conditions. On the other hand, the current of 20 mA isobtained under the reference condition in which the LED peak current is20 mA and the PMW value is 100%. In the case of L8 in FIG. 10 forexample, an LED peak current is 40 mA and “Lighting Rate (%)” or PWMvale is 100%, and then 40 mA is obtained in LED. In the case of L8 inFIG. 10, the same current as that of reference condition, 20 mA, isobtained when an LED peak current is 40 mA and PWM value is 50%. In thiscase PWM ratio of 2.0 is obtained by dividing 100% by 50%.

In the example of FIG. 10, the light source L8 (lighting rate is 100 anda PWM ratio is 2.00) and the light source L9 (lighting rate is 97 and aPWM ratio is 1.94) exceeds 1.0 indicative of the same luminance that isrealized at the maximum PWM value 100% included in the referenceconditions. Furthermore, the PWM ratios of the light sources L8 and L9are higher than those of the other light sources L1 through L7 and L10.That is to say, a heavy load is imposed on the light source L8 or L9.Such a state is a factor in a decrease in the lifetime of a lightsource.

With the display device 10 an upper limit value is set for a lightingrate so as not to impose a heavy load on a light source L. An upperlimit value is set in a predetermined range. For example, an upper limitvalue is set in the range between a lighting rate which does not causethe luminance below the maximum luminance obtained by an image signalSRGB and a lighting rate corresponding to a peak value of drive currentby which a light source L is driven. Image signal values included in theimage signal SRGB fluctuate. In the second embodiment, however, an upperlimit value is set on the basis of the maximum luminance obtained by theimage signal SRGB. In the examples of FIGS. 9 and 10, an upper limitvalue is in the range between 50% corresponding to the maximum PWM value100% of the reference conditions and 100% corresponding to an LED peakcurrent of 40 mA. An upper limit value is set properly. However, anupper limit value is set according to an average current valuedetermined by a peak current value and a lighting rate of a light sourceL.

In the following description the upper limit value of a lighting rate isset to 62.5%. If a lighting rate is 62.5%, then the ratio of thislighting rate to the maximum PWM value 100% included in the referenceconditions is 1.25.

A process performed by the lighting level determination unit 26 on theabove conditions will be described by the use of FIGS. 11 through 14.

The tentative lighting level information 70 illustrated in FIG. 10 isinputted to the lighting level determination unit 26. FIG. 11illustrates luminance distribution detected at the time of lighting eachlight source at a tentative lighting level.

FIG. 11 illustrates luminance distribution in the LY direction in anarea of the backlight 50 illustrated in FIG. 9. FIG. 11 illustratesluminance distribution for the light sources L4 through L10. Luminancedistribution for the light sources L1 through L3 is omitted. The sameapplies to FIGS. 12 through 14.

A required luminance value 81 indicated by a dashed line in FIG. 11 is arequired luminance value calculated by the image analysis unit 23 for ablock. A solid line indicates luminance distribution for each lightsource L. In particular, the luminance distribution for the lightsources L7 through L10 is marked with numbers. Hereinafter the luminancedistribution for the light sources L7, L8, L9, and L10 will be indicatedby luminance 82, 83, 84, and 85 respectively. Combined luminance 86indicates luminance distribution obtained by combining the luminancedistribution for the light sources L4 through L10. The lighting rate100% marked with the number 87 and indicated by a dot-dash lineindicates the upper limit of luminance at the time of lighting a lightsource L at a lighting rate of 100%.

As illustrated in FIG. 11, if the light sources L4 through L10 arelighted at the tentative lighting levels indicated in the tentativelighting level information 70 illustrated in FIG. 10, the luminance 83of the light source L8 and the luminance 84 of the light source L9 arehigh and close to a lighting rate of 100%. The lighting leveldetermination unit 26 has set the upper limit value of a lighting rateto 62.5%, so the lighting rates of the light sources L8 and L9 exceedthe upper limit value. Accordingly, the lighting rates of the lightsources L8 and L9 are limited to 62.5%.

FIG. 12 illustrates luminance distribution detected at the time oflimiting a lighting level of a light source by an upper limit value.

A lighting rate upper limit value 88 indicated in FIG. 12 by a chaindouble-dashed line indicates the upper limit of luminance at the time oflighting a light source L at a lighting rate of 62.5%. As illustrated inFIG. 12, lighting levels of the light sources L8 and L9 are limited tothe upper limit value. Accordingly, the maximum value of luminance 83 aof the light source L8 and the maximum value of luminance 84 a of thelight source L9 decrease. As a result, combined luminance 86 a is lowerthan the required luminance value 81. The lighting level determinationunit 26 performs a lighting level determination process in order in onedirection parallel to the direction (LY direction) in which the lightsources L are arranged in the sidelight light source 52. In the exampleof FIG. 12, the lighting level determination unit 26 corrects atentative lighting level of a light source L next to a light source Lwhose tentative lighting level is limited from the leftmost light sourceL4 to the rightmost light source L10 in the sidelight light source 52illustrated in FIG. 9. That is to say, the lighting level determinationunit 26 considers the light source L10 adjacent to the light source L9on the right side as a light source whose tentative lighting level is tobe corrected, and calculates a lighting level which satisfies a requiredluminance value for a block corresponding to the light sources L8 andL9. When a calculated lighting rate of the light source L10 exceeds theupper limit value, the lighting level determination unit 26 limits alighting rate of the light source L10 to the upper limit value.

FIG. 13 illustrates luminance distribution detected at the time ofincreasing a lighting level of the next light source on the right side.

In the example of FIG. 13, a calculated lighting rate of the lightsource L10 which compensates for a reduction in the luminance of thelight sources L8 and L9 exceeds the lighting rate upper limit value 88,so a lighting rate of the light source L10 is limited to the upper limitvalue. Furthermore, combined luminance 86 b increases with an increasein the maximum value of luminance 85 b of the light source L10. However,the combined luminance 86 b is still lower than the required luminancevalue 81. The lighting level determination unit 26 searches for a lightsource next to the light source L10 in the direction from the lightsource L4 to the light source L10. However, there is no light sourcenext to the light source L10 in this direction, so the process in thisdirection ends. Next, the lighting level determination unit 26 searchesin the opposite direction for a light source whose tentative lightinglevel is to be corrected. In the example of FIG. 13, the lighting leveldetermination unit 26 makes a search in order in the direction from thelight source L10 to the light source L4 and detects the light source L7adjacent to the light source L8 on the left side as a light source whosetentative lighting level is to be corrected. The lighting leveldetermination unit 26 calculates a lighting level which satisfies therequired luminance value for the block corresponding to the lightsources L8 and L9 and determines a lighting level of the light source L7according to the calculated lighting level. This is the same with thelight source L10.

FIG. 14 illustrates luminance distribution detected at the time ofincreasing a lighting level of a next light source on the left side.

As illustrated in FIG. 14, the maximum value of luminance 82 c of thelight source L7 increases because its lighting level is larger than atentative lighting level as a result of a correction. As a result,combined luminance 86 c satisfies the required luminance value 81.

The combined luminance 86 c satisfies the required luminance value 81,so the tentative lighting levels of the light sources L1 through L6which are not corrected are set as lighting levels. As a result,lighting levels of all the light sources L are determined.

FIG. 15 illustrates an example of lighting level information.

As indicated in lighting level information 71, lighting rates of thelight sources L8 and L9 are limited to 62.5% which is the upper limitvalue. On the other hand, a lighting rate of the light source L10adjacent to the light source L9 on the right side rises to 62.5% and alighting rate of the light source L7 adjacent to the light source L8 onthe left side rises to 52%. As has been described, at the time when thetentative lighting levels are calculated, a heavy load is imposed oneach of the light sources L8 and L9. However, lighting levels of thelight sources L8 and L9 are reduced and the light source L7 adjacent tothe light source L8 on the left side and the light source L10 adjacentto the light source L9 on the right side compensate for a reduction inluminance. By doing so, the load on each of the light sources L8 and L9is reduced.

As has been described, in the second embodiment a heavy load on a lightsource L is reduced. This reduces deterioration of the light source L.In addition, surrounding light sources compensate for lack of luminancecaused by limiting lighting levels. As a result, the luminancedistribution of the backlight 50 satisfies a required luminance value.Accordingly, it is possible to prevent deterioration of a light sourcewithout degrading image quality.

A procedure for a backlight control process performed by the displaydevice 10 will now be described by the use of FIGS. 16 through 19.

FIG. 16 is a flow chart of a procedure for a backlight control process.

An image signal SRGB is inputted every image frame cycle from the imageoutput section 11 to the signal processing section 20. When input of theimage signal SRGB is begun, the signal processing section 20 begins aprocess and outputs the image signal SRGB to the timing generation unit21, the display signal conversion unit 22, and the image analysis unit23.

(Step S01) The image analysis unit 23 analyzes the acquired image signalSRGB and calculates a required luminance value for each block. Forexample, the image analysis unit 23 analyzes the image signal SRGBcorresponding to each block and calculates 1/α.

(Step S02) On the basis of the required luminance value calculated instep S01 and the light-source-specific LUT 240 stored in the lightsource data storage unit 24, the tentative lighting level calculationunit 25 calculates a tentative lighting level of each light source Lwhich satisfies the required luminance value.

(Step S03) The lighting level determination unit 26 performs in orderthree steps S03, S04, and S05 to determine a lighting level of eachlight source L. In the first stage, the lighting level determinationunit 26 limits a lighting level. To be concrete, the lighting leveldetermination unit 26 detects a light source L whose tentative lightinglevel exceeds an upper limit value, and limits a lighting level of thedetected light source L to the upper limit value.

(Step S04) The lighting level determination unit 26 performs firstluminance correction as the second stage. To be concrete, the lightinglevel determination unit 26 performs luminance correction in onedirection in which the light sources L are arranged in the sidelightlight source 52. In this example, a tentative lighting level of a lightsource L corresponding to a block on the right side of a blockcorresponding to the light source L whose lighting level is limited tothe upper limit value is to be corrected in the rightward direction inFIG. 9, that is to say, in the direction from the light source L1 to thelight source L10. In the example of FIG. 9, a light source Lcorresponding to a block on the right side of a block corresponding tothe light source L whose lighting level is limited to the upper limitvalue is a light source L adjacent on the right side to the light sourceL whose lighting level is limited to the upper limit value. Thiscorrection compensates for a reduction in the entire luminance caused bythe lighting level limitation in step S03.

(Step S05) The lighting level determination unit 26 performs secondluminance correction as the third stage. To be concrete, a tentativelighting level of a light source L corresponding to a block on the leftside of the block corresponding to the light source L whose lightinglevel is limited to the upper limit value is to be corrected in theleftward direction opposite to the direction in step S04, that is tosay, in the direction from the light source L10 to the light source L1.By doing so, the lighting level determination unit 26 corrects luminancefor the block from a side on which a reduction in luminance is notcompensated for by the first luminance correction in step S04.Furthermore, a tentative lighting level of a light source L on which thelighting level limitation, the first luminance correction, or the secondluminance correction is not performed is considered as a lighting level.As a result, all lighting level signals SBL are generated. The lightinglevel determination unit 26 outputs the generated all lighting levelsignals SBL to the light source drive section 60.

(Step S06) The lighting level determination unit 26 generates on thebasis of the generated all lighting level signals SBL and thelight-source-specific LUT 240 BL luminance information indicative of theluminance distribution of the backlight 50 at the time of lighting thesidelight light source 52 with the generated all lighting level signalsSBL, and outputs the BL luminance information to the display signalconversion unit 22. On the basis of the BL luminance information, thedisplay signal conversion unit 22 corrects a display signal SRGBWobtained by converting the image signal SRGB. By doing so, a displaysignal SRGBW suited to the luminance of the corresponding backlight 50is generated.

The lighting level limitation, the first luminance correction, and thesecond luminance correction will now be described in detail. In thefollowing description, a light source corresponding to a block to beprocessed is indicated by a light source Ln, a light sourcecorresponding to the next block on the right side is indicated by alight source L(n+1), and a light source corresponding to the next blockon the left side is indicated by a light source L(n−1).

FIG. 17 is a flow chart of a procedure for the lighting level limitationin the lighting level determination.

(Step S301) The lighting level determination unit 26 initializes a blocknumber to 1 to perform a process on a block-by-block basis. As statedabove, a block area corresponds to a light source Ln.

(Step S302) On the basis of the light-source-specific LUT 240, thelighting level determination unit 26 calculates the luminance value 1/αof a block detected at the time of lighting the light source Lncorresponding to the block at a tentative lighting level.

(Step S303) The lighting level determination unit 26 determines whetheror not the luminance value 1/α of the block which is detected at thetime of lighting the light source Ln at the tentative lighting level andwhich is calculated in step S302 is smaller than the required luminancevalue 1/α. If the calculated luminance value 1/α of the block is smallerthan the required luminance value, then the lighting level determinationunit 26 determines that the luminance value 1/α of the block does notsatisfy the required luminance value, and proceeds to step S304. If thecalculated luminance value 1/α of the block is greater than or equal tothe required luminance value, then the lighting level determination unit26 determines that the luminance value 1/α of the block satisfies therequired luminance value, and proceeds to step S306.

(Step S304) If the luminance value 1/α of the block is smaller than therequired luminance value, then the lighting level determination unit 26calculates the differential between them. On the basis of thelight-source-specific LUT 240, the lighting level determination unit 26then calculates the number of times the differential is greater than aluminance value in the position obtained from the light-source-specificLUT 240. A calculated value corresponds to the differential value 1/α.

(Step S305) The lighting level determination unit 26 adds thedifferential value 1/α calculated in step S304 to the tentative lightinglevel of the light source Ln corresponding to the block to update thetentative lighting level.

(Step S306) The lighting level determination unit 26 compares atentative lighting level of the light source Ln corresponding to theblock with an upper limit value to determine whether or not thetentative lighting level is larger than the upper limit value. If thetentative lighting level is larger than the upper limit value, then thelighting level determination unit 26 proceeds to step S307. If thetentative lighting level is smaller than or equal to the upper limitvalue, then the lighting level determination unit 26 proceeds to stepS308.

(Step S307) The tentative lighting level is larger than the upper limitvalue, so the lighting level determination unit 26 limits a tentativelighting level of the light source Ln to the upper limit value.Furthermore, the lighting level determination unit 26 sets a flagcorresponding to the block in limitation information indicative ofblocks for which tentative lighting levels of light sources are limitedto the upper limit value.

(Step S308) The lighting level determination unit 26 determines whetheror not a process has been performed on all blocks. If there is a blockon which a process has not been performed yet, then the lighting leveldetermination unit 26 proceeds to step S309. If a process has beenperformed on all the blocks, then the lighting level determination unit26 ends the lighting level limitation.

(Step S309) The lighting level determination unit 26 increments theblock number by one and returns to step S302.

By performing the above procedure, a lighting level of a light source Lwhose tentative lighting level exceeds the upper limit value is limitedto the upper limit value. Furthermore, a flag indicative of limitationinformation is set for a block for which a lighting level of a lightsource L is limited to the upper limit value to pass the limitationinformation to the next process.

The first luminance correction will now be described.

FIG. 18 is a flow chart of a procedure for the first luminancecorrection in the lighting level determination.

(Step S401) The lighting level determination unit 26 initializes a blocknumber to 1.

(Step S402) The lighting level determination unit 26 refers to thelimitation information set in the lighting level limitation illustratedin FIG. 17, and determines whether or not a flag corresponding to theblock is set. If a flag is set, that is to say, a lighting level of thelight source Ln corresponding to the block is limited, then the lightinglevel determination unit 26 proceeds to step S403. If a flag is not set,that is to say, a lighting level of the light source Ln corresponding tothe block is not limited, then the lighting level determination unit 26proceeds to step S409.

(Step S403) A flag corresponding to the block is set, so the lightinglevel determination unit 26 calculates on the basis of thelight-source-specific LUT 240 the luminance value 1/α of the blockdetected at the time of lighting the light source Ln corresponding tothe block at a limited lighting level.

(Step S404) The lighting level determination unit 26 determines whetheror not the luminance value 1/α of the block calculated in step S403 issmaller than the required luminance value 1/α. If the calculatedluminance value 1/α of the block is smaller than the required luminancevalue, then the lighting level determination unit 26 determines that theluminance value 1/α of the block does not satisfy the required luminancevalue, and proceeds to step S405. If the calculated luminance value 1/αof the block is greater than or equal to the required luminance value,then the lighting level determination unit 26 determines that theluminance value 1/α of the block satisfies the required luminance value,and proceeds to step S407.

(Step S405) If the luminance value 1/α of the block is smaller than therequired luminance value, then the lighting level determination unit 26calculates the differential between them. On the basis of thelight-source-specific LUT 240, the lighting level determination unit 26then calculates the number of times the differential is greater than aluminance value in the position of a block adjacent on the right side tothe above block obtained from the light-source-specific LUT 240. Acalculated value corresponds to the differential value 1/α.

(Step S406) The lighting level determination unit 26 adds thedifferential value 1/α calculated in step S405 to a tentative lightinglevel of the light source L(n+1) corresponding to the block adjacent onthe right side to the above block to update the tentative lightinglevel.

(Step S407) The lighting level determination unit 26 compares atentative lighting level after update of the light source L(n+1)corresponding to the block adjacent on the right side to the above blockwith the upper limit value to determine whether or not the tentativelighting level after update is larger than the upper limit value. If thetentative lighting level after update is larger than the upper limitvalue, then the lighting level determination unit 26 proceeds to stepS408. If the tentative lighting level after update is smaller than orequal to the upper limit value, then the lighting level determinationunit 26 proceeds to step S409.

(Step S408) The tentative lighting level after update is larger than theupper limit value, so the lighting level determination unit 26 limits atentative lighting level of the light source L(n+1) to the upper limitvalue. Furthermore, the lighting level determination unit 26 sets a flagcorresponding to the next block on the right side in the limitationinformation indicative of blocks for which tentative lighting levels oflight sources are limited to the upper limit value.

(Step S409) The lighting level determination unit 26 determines whetheror not a process has been performed on all the blocks. If there is ablock on which a process has not been performed yet, then the lightinglevel determination unit 26 proceeds to step S410. If a process has beenperformed on all the blocks, then the lighting level determination unit26 ends the first luminance correction.

(Step S410) The lighting level determination unit 26 increments theblock number by one and returns to step S402.

By performing the above procedure, a lighting level is corrected inorder from a light source corresponding to a block adjacent on the rightside to a block for which a tentative lighting level of a light sourceexceeds an upper limit value. If a lighting level after correctionexceeds the upper limit value, then luminance is corrected by a lightsource corresponding to next block but one on the right side. A lightinglevel correction is repeated in this way until a light source whosetentative lighting level does not exceed the upper limit value isdetected or until the last light source.

The second luminance correction will now be described.

FIG. 19 is a flow chart of a procedure for the second luminancecorrection in the lighting level determination.

(Step S501) The lighting level determination unit 26 initializes a blocknumber to 1.

(Step S502) The lighting level determination unit 26 refers to thelimitation information and determines whether or not a flagcorresponding to the block is set. If a flag is set, that is to say, alighting level of the light source Ln corresponding to the block islimited, then the lighting level determination unit 26 proceeds to stepS503. If a flag is not set, that is to say, a lighting level of thelight source Ln corresponding to the block is not limited, then thelighting level determination unit 26 proceeds to step S509.

(Step S503) A flag corresponding to the block is set, so the lightinglevel determination unit 26 calculates on the basis of thelight-source-specific LUT 240 the luminance value 1/α of the blockdetected at the time of lighting the light source Ln corresponding tothe block at a limited lighting level.

(Step S504) The lighting level determination unit 26 determines whetheror not the luminance value 1/α of the block calculated in step S503 issmaller than the required luminance value 1/α. If the calculatedluminance value 1/α of the block is smaller than the required luminancevalue, then the lighting level determination unit 26 determines that theluminance value 1/α of the block does not satisfy the required luminancevalue, and proceeds to step S505. If the calculated luminance value 1/αof the block is greater than or equal to the required luminance value,then the lighting level determination unit 26 determines that theluminance value 1/α of the block satisfies the required luminance value,and proceeds to step S507.

(Step S505) If the luminance value 1/α of the block is smaller than therequired luminance value, then the lighting level determination unit 26calculates the differential between them. On the basis of thelight-source-specific LUT 240, the lighting level determination unit 26then calculates the number of times the differential is greater than aluminance value in the position of a block adjacent on the left side tothe above block obtained from the light-source-specific LUT 240. Acalculated value corresponds to the differential value 1/α.

(Step S506) The lighting level determination unit 26 adds thedifferential value 1/α calculated in step S505 to a tentative lightinglevel of the light source L(n−1) corresponding to the block adjacent onthe right side to the above block to update the tentative lightinglevel.

(Step S507) The lighting level determination unit 26 compares atentative lighting level after update of the light source L(n−1)corresponding to the block adjacent on the left side to the above blockwith the upper limit value to determine whether or not the tentativelighting level after update is larger than the upper limit value. If thetentative lighting level after update is larger than the upper limitvalue, then the lighting level determination unit 26 proceeds to stepS508. If the tentative lighting level after update is smaller than orequal to the upper limit value, then the lighting level determinationunit 26 proceeds to step S509.

(Step S508) The tentative lighting level after update is larger than theupper limit value, so the lighting level determination unit 26 limits atentative lighting level of the light source L(n−1) to the upper limitvalue.

(Step S509) The lighting level determination unit 26 determines whetheror not a process has been performed on all the blocks. If there is ablock on which a process has not been performed yet, then the lightinglevel determination unit 26 proceeds to step S510. If a process has beenperformed on all the blocks, then the lighting level determination unit26 ends the second luminance correction.

(Step S510) The lighting level determination unit 26 increments theblock number by one and returns to step S502.

By performing the above procedure, a lighting level is corrected inorder from a light source corresponding to a block adjacent on the leftside to a block for which a tentative lighting level of a light sourceexceeds an upper limit value.

As has been described, a reduction in the luminance of the backlight 50caused by limiting a lighting level of the light source Ln to an upperlimit value is compensated for by surrounding light sources and alighting level which satisfies a required luminance value is determined.If a lighting level of a light source corresponding to a block adjacenton the left side to a block for which a tentative lighting level of alight source exceeds the upper limit value also exceeds the upper limitvalue, then luminance is corrected by a light source corresponding tonext block but one on the left side. This is the same with the firstluminance correction. A lighting level correction is repeated in thisway until a light source whose tentative lighting level does not exceedthe upper limit value is detected.

With the above procedures, corrections are made in order in bothdirections in which the light sources L are arranged, and the processends. However, the same procedures may be performed again. Furthermore,the same process may be performed not only in the leftward and rightwarddirections (LY direction in FIG. 9) but also in the upward and downwarddirections (LX direction in FIG. 9) perpendicular to the leftward andrightward directions, depending on the arrangement of light sources or amethod for making a division into blocks.

The above processing functions can be realized with a computer. In thatcase, a program in which the contents of the functions that the displaydevice has are described is provided. By executing this program on thecomputer, the above processing functions are realized on the computer.This program may be recorded on a computer readable record medium. Acomputer readable record medium may be a magnetic storage device, anoptical disk, a magneto-optical recording medium, a semiconductormemory, or the like. A magnetic storage device may be a hard disk drive(HDD), a flexible disk (FD), a magnetic tape, or the like. An opticaldisk may be a digital versatile disc (DVD), a DVD-random access memory(RAM), a compact disc read only memory (CD-ROM), a CD-recordable(R)/rewritable (RW), or the like. A magneto-optical recording medium maybe a magneto-optical disk (MO) or the like.

To place the program on the market, portable record media, such as DVDsor CD-ROMs, on which it is recorded are sold. Alternatively, the programis stored in advance in a storage unit of a server computer and istransferred from the server computer to another computer via a network.

When a computer executes this program, it will store the program, whichis recorded on a portable record medium or which is transferred from theserver computer, in, for example, its storage unit. Then the computerreads the program from its storage unit and performs processes incompliance with the program. The computer may read the program directlyfrom a portable record medium and perform processes in compliance withthe program. Furthermore, each time the program is transferred from theserver computer connected via a network, the computer may performprocesses in order in compliance with the program it receives.

In addition, at least a part of the above processing functions may berealized by an electronic circuit such as a digital signal processor(DSP), an application specific integrated circuit (ASIC), or aprogrammable logic device (PLD).

According to one aspect, there is provided a display device including:an image display panel whose display is controlled on the basis of animage signal; a backlight which includes a plurality of light sourcesand which lights the image display panel from behind; and a displaycontrol section which calculates on the basis of the image signal arequired luminance value of the backlight for each area obtained bydividing a display surface of the image display panel, which calculatesa tentative lighting level of each of the plurality of light sources onthe basis of luminance distribution information for the backlight storedin advance and the required luminance value, which sets the lightinglevel of a first light source whose tentative lighting level exceeds adetermined upper limit value to the upper limit value, which calculatesand determines the lighting level of a second light source whosetentative lighting level does not exceed the upper limit value on thebasis of the lighting level of the first light source, the luminancedistribution information, and the required luminance value, and whichcontrols the backlight by the lighting levels.

In the display device, the display control section determines thelighting level of the second light source adjacent to the first lightsource.

Further, in the display device, the display control section compares thecalculated lighting level of the second light source with the upperlimit value, sets, at the time of the calculated lighting level of thesecond light source being larger than the upper limit value, thelighting level of the second light source to the upper limit value, andrepeats determination of the lighting level of the second light sourcewhose lighting level is not determined until the calculated lightinglevel of the second light source becomes smaller than or equal to theupper limit value.

Still further, in the display device, the plurality of light sources arearranged in at least one direction, and the display control sectionsearches through the plurality of light sources in order in the onedirection, detects the first light source, determines the lighting levelof the first light source and a lighting level of the second lightsource arranged after the first light source, searches through theplurality of light sources in order in a direction opposite to the onedirection, detects the first light source, and determines a lightinglevel of the first light source and a lighting level of the second lightsource arranged after the first light source.

Still further, in the display device, the image display panel includespixels each of which includes a first subpixel which displays a firstprimary color, a second subpixel which displays a second primary color,a third subpixel which displays a third primary color, and a fourthsubpixel which displays a fourth color, and the display control sectioncalculates, on the basis of color information about the first primarycolor, the second primary color, and the third primary color included inthe image signal, a conversion coefficient used for converting the imagesignal to a display signal by which display control of the image displaypanel is performed, and calculates the required luminance value on thebasis of the conversion coefficient.

Still further, in the display device, the luminance of the pixelsobtained by the display signal after conversion based on the conversioncoefficient is higher than the luminance of the pixels obtained by theimage signal, and the upper limit value is set to a value which is notlower than the maximum luminance obtained by the image signal.

In addition, according to one aspect, there is provided a method fordriving a display device including an image display panel whose displayis controlled on the basis of an image signal and a backlight whichincludes a plurality of light sources and which lights the image displaypanel from behind. The method includes: calculating, by a displaycontrol section, on the basis of the image signal a required luminancevalue of the backlight for each area obtained by dividing a displaysurface of the image display panel; calculating, by the display controlsection, a tentative lighting level of each of the plurality of lightsources on the basis of luminance distribution information for thebacklight stored in advance and the required luminance value; setting,by the display control section, the lighting level of a first lightsource whose tentative lighting level exceeds a determined upper limitvalue to the upper limit value and calculating and determining, by thedisplay control section, the lighting level of a second light sourcewhose tentative lighting level does not exceed the upper limit value onthe basis of the lighting level of the first light source, the luminancedistribution information, and the required luminance value; andcontrolling, by the display control section, the backlight by thelighting levels.

All examples and conditional language provided herein are intended forthe pedagogical purposes of aiding the reader in understanding theinvention and the concepts contributed by the inventor to further theart, and are not to be construed as limitations to such specificallyrecited examples and conditions, nor does the organization of suchexamples in the specification relate to a showing of the superiority andinferiority of the invention. Although one or more embodiments of thepresent invention have been described in detail, it should be understoodthat various changes, substitutions, and alterations could be madehereto without departing from the spirit and scope of the invention.

It should be understood that various changes and modifications to thepresently preferred embodiments described herein will be apparent tothose skilled in the art. Such changes and modifications can be madewithout departing from the spirit and scope of the present subjectmatter and without diminishing its intended advantages. It is thereforeintended that such changes and modifications be covered by the appendedclaims.

The invention is claimed as follows:
 1. A display device comprising: animage display panel whose display is controlled on the basis of an imagesignal, the image display panel being divided into a plurality ofdivided areas including a first divided area and a second divided area;a backlight including a plurality of light sources including a firstlight source corresponding to the first divided area and a second lightsource corresponding to the second divided area adjacent to the firstlight source, and configured to light the image display panel frombehind; and a display controller configured to set an upper limit valueof lighting levels of the first light source and the second lightsource, and calculate a first required luminance value for the firstlight source divided area and a second required luminance value for thesecond light source divided area on the basis of the image signal of thefirst divided area and the second divided area, wherein the displaycontroller is configured to set a first lighting level of the firstlight source to the upper limit value when the first required luminancevalue exceeds the upper limit value, increase a second lighting level ofthe second light source on the basis of the first lighting level and theimage signal of the first divided area and the second divided area tosatisfy the first required luminance value when the second requiredluminance value does not exceed the upper limit value, and set thesecond lighting level to the upper limit value when the second requiredluminance value exceeds the upper limit value.
 2. The display deviceaccording to claim 1, wherein the display controller further comparesthe second lighting level of the second light source with the upperlimit value, sets the second lighting level of the second light sourceto the upper limit value when the second lighting level of the secondlight source is larger than the upper limit value, determines a thirdlighting level of a third light source which is adjacent to the secondlight source on the basis of the first lighting level, the secondlighting level, and the image signal of the first divided area and thesecond divided area to satisfy the first required luminance value forthe first light source divided area and repeats determination of thelighting level of a rest of the light sources whose lighting level isdetermined to be smaller than or equal to the upper limit value.
 3. Thedisplay device according to claim 1, wherein: the plurality of lightsources are arranged in at least one direction; and the displaycontroller searches through the plurality of light sources in order inthe one direction, detects the first light source, determines the firstlighting level of the first light source and the second lighting levelof the second light source arranged after the first light source,searches through the plurality of light sources in order in a directionopposite to the one direction, detects the first light source, anddetermines the first lighting level of the first light source and thesecond lighting level of the second light source arranged after thefirst light source.
 4. The display device according to claim 1, wherein:the image display panel includes pixels each including a first subpixelwhich displays a first primary color, a second subpixel which displays asecond primary color, a third subpixel which displays a third primarycolor, and a fourth subpixel which displays a fourth color; and thedisplay controller calculates, on the basis of color information aboutthe first primary color, the second primary color, and the third primarycolor included in the image signal, a conversion coefficient used forconverting the image signal to a display signal by which display controlof the image display panel is performed, and calculates the firstrequired luminance value and the second required luminance value on thebasis of the conversion coefficient.
 5. The display device according toclaim 4, wherein: luminance of the pixels in the display signal afterconversion based on the conversion coefficient is higher than luminanceof the pixels in the image signal; and the upper limit value is set to avalue which is not lower than maximum luminance obtained by the imagesignal.
 6. A driving display method to be executed by a display deviceincluding an image display panel divided into a plurality of areasincluding a first divided area and a second divided area, a backlightand a display controller, display of the image display panel beingcontrolled on the basis of an image signal, the backlight including aplurality of light sources including a first light source correspondingto the first divided area and a second light source corresponding to thesecond divided area adjacent to the first light source and lighting theimage display panel from behind, the display controller controlling thefirst light source and the second light source, the driving displaymethod comprising: setting, by the display controller, an upper limitvalue of lighting levels of the first light source and the second lightsource, calculating a first required luminance value for the first lightsource divided area and a second required luminance value for the secondlight source divided area on the basis of the image signal of the firstdivided area and the second divided area, setting, by the displaycontroller, a first lighting level of the first light source to theupper limit value when the first required luminance value exceeds theupper limit value, increasing, by the display controller, a secondlighting level of the second light source on the basis of the firstlighting level and the image signal of the first divided area and thesecond divided area to satisfy the first required luminance value whenthe second required luminance value does not exceed the upper limitvalue, and setting, by the display controller, the second lighting levelto the upper limit value when the second required luminance valueexceeds the upper limit value.